DRINKING WATER

GettyImages-2176083692 hurricane Building Resilient Water Treatment: How Ozone Systems Help Utilities Prepare for Extreme Weather

Ozone systems build resilience into water treatment. They ensure utilities remain chemically self-sufficient, allow fast recovery from power outages, and handle rapid water quality shifts.

DRINKING WATER CASE STUDIES AND WHITE PAPERS

DRINKING WATER APPLICATION NOTES

DRINKING WATER PRODUCTS

Engineered and built for dependable performance, the TrojanUVSwift® requires a minimal number of lamps to treat a given flow, and is serviceable from one side for easy maintenance. It also incorporates innovative features to reduce operation and maintenance (O&M) costs, including variable output lamp drivers and our revolutionary ActiClean® automatic sleeve wiping system.

Loprest has been providing ion exchange treatment systems for the removal of arsenic, nitrate, perchlorate, hardness, fluoride and other contaminants for many decades. 

 

Get benchtop lab accuracy in an easy-to-use, easy-to-maintain, wireless, handheld instrument designed for diverse, demanding, water quality testing applications. Select from a variety of pocket testers, each featuring simultaneous measurement of Temperature and one critical parameter:

Trilogy is a modular laboratory fluorometer offering sensitive, precise measurements across multiple applications. With interchangeable modules for chlorophyll, CDOM, turbidity, and more, Trilogy delivers laboratory-grade performance with flexibility.

Ozone treatment for water and wastewater has been utilized successfully for several decades and continues to be a viable disinfection solution for both municipal and industrial plants, worldwide.

The launch of the world’s first ready-to-use reagent packages for photometric analysis in the 1960’s had a substantial effect on water analysis. Today Hach® TNTplus® Vial Tests and photometers are indispensable elements of both process control and compliance monitoring.

LATEST INSIGHTS ON DRINKING WATER

  • Amazon and Xylem partner to tackle Mexico’s leaking water systems as the country balances water scarcity and a growing tech sector.

  • Water scarcity is increasingly impacting sectors from agriculture and energy to urban planning and high-tech manufacturing. Recently, industry leaders gathered to explore how new technologies and complex industrial demands are forcing a fundamental rethinking of water infrastructure.

  • Nobel-winning molecular materials are poised to reinvent purification, desalination, and reuse.

  • Researchers have developed polyimide-based membranes for membrane distillation (MD) that overcome three persistent issues in membranes for water treatment and gas separations: the need for pore-forming chemicals that prevent recycling, performance degradation due to pore wetting and fouling, and the inherent trade-off between high water flux and selectivity.

  • Small municipalities and industrial sites face constant pressure: deliver safe, stable water with limited resources and tight deadlines. Traditional on-site construction can stretch project schedules by months and introduce quality and cost risks. By shifting much of the fabrication off-site, these risks are dramatically reduced.

  • The 2024 hurricane season was one of the most severe on record, creating unprecedented destruction to the tune of $182.7 billion worth of damage. Scientists predict that this year's storm season, which officially began June 1, will likely be highly active and volatile as well. As hurricanes become more difficult to accurately predict and prepare for, the damage caused by burst pipes, flooding, downed trees and debris, and disrupted utilities is also increasing.

DRINKING WATER VIDEOS

EXO, a state-of-the art water quality monitoring platform, is designed to address the many challenges of collecting accurate field data in the natural environment.

The TROLL® 9500 Water Quality Instrument simplifies multiparameter monitoring. The TROLL 9500 is a powerful, portable unit that houses up to nine water quality sensors, internal power, and optional data logging capabilities.

Why have only 20% of water utilities deployed an AMI fixed network?  If you are considering a fixed network, I've got something you seriously need to consider prior to soliciting quotations or putting out your RFP. The question is, who is going to manage the network infrastructure? Do you have qualified individuals within your utility ready to continuously monitor, maintain and manage the network? In this video, we're going to discuss some of the options available for water utilities today: a utility managed network versus a network as a service agreement (NaaS).

O’Brien, Texas is just one of thousands of small communities in the United States that struggle to find the resources to ensure that the water coming out of the tap is safe to drink. The recent budget proposal by the Trump administration will only make matters worse. Watch this documentary short produced by Tom Rosenberg and Earth Institute fellow Madison Condon details one shrinking town’s drinking water crisis.

Bill Gates challenges Jimmy to taste test water from the Omniprocessor, which turns sewage into clean drinking water.

ABOUT DRINKING WATER

In most developed countries, drinking water is regulated to ensure that it meets drinking water quality standards. In the U.S., the Environmental Protection Agency (EPA) administers these standards under the Safe Drinking Water Act (SDWA)

Drinking water considerations can be divided into three core areas of concern:

  1. Source water for a community’s drinking water supply
  2. Drinking water treatment of source water
  3. Distribution of treated drinking water to consumers

Drinking Water Sources

Source water access is imperative to human survival. Sources may include groundwater from aquifers, surface water from rivers and streams and seawater through a desalination process. Direct or indirect water reuse is also growing in popularity in communities with limited access to sources of traditional surface or groundwater. 

Source water scarcity is a growing concern as populations grow and move to warmer, less aqueous climates; climatic changes take place and industrial and agricultural processes compete with the public’s need for water. The scarcity of water supply and water conservation are major focuses of the American Water Works Association.

Drinking Water Treatment

Drinking Water Treatment involves the removal of pathogens and other contaminants from source water in order to make it safe for humans to consume. Treatment of public drinking water is mandated by the Environmental Protection Agency (EPA) in the U.S. Common examples of contaminants that need to be treated and removed from water before it is considered potable are microorganisms, disinfectants, disinfection byproducts, inorganic chemicals, organic chemicals and radionuclides.

There are a variety of technologies and processes that can be used for contaminant removal and the removal of pathogens to decontaminate or treat water in a drinking water treatment plant before the clean water is pumped into the water distribution system for consumption.

The first stage in treating drinking water is often called pretreatment and involves screens to remove large debris and objects from the water supply. Aeration can also be used in the pretreatment phase. By mixing air and water, unwanted gases and minerals are removed and the water improves in color, taste and odor.

The second stage in the drinking water treatment process involves coagulation and flocculation. A coagulating agent is added to the water which causes suspended particles to stick together into clumps of material called floc. In sedimentation basins, the heavier floc separates from the water supply and sinks to form sludge, allowing the less turbid water to continue through the process.

During the filtration stage, smaller particles not removed by flocculation are removed from the treated water by running the water through a series of filters. Filter media can include sand, granulated carbon or manufactured membranes. Filtration using reverse osmosis membranes is a critical component of removing salt particles where desalination is being used to treat brackish water or seawater into drinking water.

Following filtration, the water is disinfected to kill or disable any microbes or viruses that could make the consumer sick. The most traditional disinfection method for treating drinking water uses chlorine or chloramines. However, new drinking water disinfection methods are constantly coming to market. Two disinfection methods that have been gaining traction use ozone and ultra-violet (UV) light to disinfect the water supply.

Drinking Water Distribution

Drinking water distribution involves the management of flow of the treated water to the consumer. By some estimates, up to 30% of treated water fails to reach the consumer. This water, often called non-revenue water, escapes from the distribution system through leaks in pipelines and joints, and in extreme cases through water main breaks.

A public water authority manages drinking water distribution through a network of pipes, pumps and valves and monitors that flow using flow, level and pressure measurement sensors and equipment.

Water meters and metering systems such as automatic meter reading (AMR) and advanced metering infrastructure (AMI) allows a water utility to assess a consumer’s water use and charge them for the correct amount of water they have consumed.